Promoter and exon-intron structure of the protein kinase C gene from the marine sponge Geodia cydonium: evolutionary considerations and promoter activity

We report the gene structure of a key signaling molecule from a marine sponge, Geodia cydonium. The selected gene, which codes for a classical protein kinase C (cPKC), comprises 13 exons and 12 introns; the introns are, in contrast to those found in cPKC from higher Metazoa, small in size ranging from 93 nt to 359 nt. The complete gene has a length of 4229 nt and contains exons which encode the characteristic putative regulatory and catalytic domains of metazoan cPKCs. While in the regulatory domain only one intron is in phase 0, in the catalytic domain most introns are phase 0 introns, suggesting that the latter only rarely undergo module duplication. The 5'-flanking sequence of the sponge cPKC gene contains a TATA-box like motif which is located 35-26 nt upstream from the start of the longest sequenced cDNA. This 5'-flanking sequence was analyzed for promoter activity. The longest fragment (538 nt) was able to drive the expression of luciferase in transient transfections of NIH 3T3 fibroblasts; the strong activity of the sponge promoter was found to be half the one displayed by the SV40 reference promoter. Deletion analysis demonstrates that the AP4 site and the GC box which is most adjacent to the TATA box are the crucial elements for maximal promoter activity. The activity of the promoter is not changed in 3T3 cells which are kept serum starved or in the presence of a phorbol ester. In conclusion, these data present the phylogenetically oldest cPKC gene which contains in the 5'-flanking region a promoter functional in the heterologous mammalian cell system.     

Protein-binding sites within the 5'' DNase I-hypersensitive region of the chicken alpha D-globin gene.

We mapped at high resolution and as a function of development the hypersensitive domain in the 5'-flanking region of the chicken alpha D-globin gene and determined the specific protein-binding sites within the domain. The domain extends from -130 to +80 nucleotides (nt) relative to the cap site. DNase I footprinting within intact embryonic erythrocyte nuclei revealed a strongly protected area from -71 to -52 nt. The same area was weakly protected in adult nuclei. A factor was present in extracts of erythrocyte nuclei from both embryos and adults that protected the sequence AAGATAAGG (-63 to -55 nt) in DNase I footprinting experiments; at higher concentrations of extract, sequences immediately adjacent (-73 to -64 and -53 to -38) were also protected. The same pattern of binding was revealed by gel mobility shift assays. The identical AAGATAAGG sequence is found in the 5'-flanking region of the beta rho gene; it competed for binding of the alpha D-specific factor, suggesting that regulatory elements are shared.     

Potential DNA-binding domains in the RAD18 gene product of Saccharomyces cerevisiae

The RAD18 gene of Saccharomyces cerevisiae is involved in the error-prone DNA repair. Its nucleotide sequence, as reported here, predicts an open reading frame of 1461 nt which corresponds to a protein of 487 amino acids, with an Mr of 55,237. This protein has three putative zinc fingers, two acidic regions and a nucleotide-binding domain, suggesting that it is a nucleic acid-binding protein with a possible regulatory role.     

Expression Enhancement of a Rice Polyubiquitin Gene Promoter

An 808 bp promoter from a rice polyubiquitin gene, rubi3, has been isolated. The rubi3 gene contained an open reading frame of 1140 bp encoding a pentameric polyubiquitin arranged as five tandem, head-to-tail repeats of 76 aa. The 1140 bp 5′ UTR intron of the gene enhanced its promoter activity in transient expression assays by 20-fold. Translational fusion of the GUS reporter gene to the coding sequence of the ubiquitin monomer enhanced GUS enzyme activity in transient expression assays by 4.3-fold over the construct containing the original rubi3 promoter (including the 5′ UTR intron) construct. The enhancing effect residing in the ubiquitin monomer coding sequence has been narrowed down to the first 9 nt coding for the first three amino acid residues of the ubiquitin protein. Mutagenesis at the third nucleotide of this 9 nt sequence still maintains the enhancing effect, but leads to translation of the native GUS protein rather than a fusion protein. The resultant 5′ regulatory sequence, consisting of the rubi3 promoter, 5′ UTR exon and intron, and the mutated first 9 nt coding sequence, has an activity nearly 90-fold greater than the rubi3 promoter only (without the 5′ UTR intron), and 2.2-fold greater than the maize Ubi1 gene promoter (including its 5′ UTR intron). The newly created expression vector is expected to enhance transgene expression in monocot plants. Considering the high conservation of the polyubiquitin gene structure in higher plants, the observed enhancement in gene expression may apply to 5′ regulatory sequences of other plant polyubiquitin genes.